/*
 * Copyright (c) 2004, Bull S.A..  All rights reserved.
 * Created by: Sebastien Decugis

 * This program is free software; you can redistribute it and/or modify it
 * under the terms of version 2 of the GNU General Public License as
 * published by the Free Software Foundation.
 *
 * This program is distributed in the hope that it would be useful, but
 * WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
 *
 * You should have received a copy of the GNU General Public License along
 * with this program; if not, write the Free Software Foundation, Inc., 59
 * Temple Place - Suite 330, Boston MA 02111-1307, USA.

 
 * This sample test aims to check the following assertion:
 *
 * This function is a cancelation point: when cancelability
 * is PTHREAD_CANCEL_DEFERRED and a cancel request falls, the thread
 * must relock the mutex before the first (if any) clean up handler is called.

 * The steps are:
 * -> Create a thread
 *   ->  this thread locks a mutex then waits for a condition
 * -> cancel the thread
 *   -> the cancelation handler will test if the thread owns the mutex.
 */
 
 /* We are testing conformance to IEEE Std 1003.1, 2003 Edition */
 #define _POSIX_C_SOURCE 200112L
 
 /* We need the XSI extention for the mutex attributes */
#ifndef WITHOUT_XOPEN
 #define _XOPEN_SOURCE	600
#endif
 /********************************************************************************************/
/****************************** standard includes *****************************************/
/********************************************************************************************/
 #include <pthread.h>
 #include <stdarg.h>
 #include <stdio.h>
 #include <stdlib.h> 
 #include <unistd.h>

 #include <errno.h>
 #include <time.h>
 #include <semaphore.h>
 
/********************************************************************************************/
/******************************   Test framework   *****************************************/
/********************************************************************************************/
 #include "testfrmw.h"
 #include "testfrmw.c"
 /* This header is responsible for defining the following macros:
  * UNRESOLVED(ret, descr);  
  *    where descr is a description of the error and ret is an int (error code for example)
  * FAILED(descr);
  *    where descr is a short text saying why the test has failed.
  * PASSED();
  *    No parameter.
  * 
  * Both three macros shall terminate the calling process.
  * The testcase shall not terminate in any other maneer.
  * 
  * The other file defines the functions
  * void output_init()
  * void output(char * string, ...)
  * 
  * Those may be used to output information.
  */

/********************************************************************************************/
/********************************** Configuration ******************************************/
/********************************************************************************************/
#ifndef VERBOSE
#define VERBOSE 1
#endif

#ifndef WITHOUT_ALTCLK
#define USE_ALTCLK  /* make tests with MONOTONIC CLOCK if supported */
#endif

/********************************************************************************************/
/***********************************    Test case   *****************************************/
/********************************************************************************************/

static struct 
{
	pthread_mutex_t mtx;
	pthread_cond_t cnd;
	int type;
	clockid_t cid;
	sem_t semA;
	sem_t semB;
	int bool;
} data;


/****  First handler that will be poped
 *  This one works only with recursive mutexes 
 */
void pthread_cond_timedwait_2_6_clnp1 (void * arg)
{
	int ret;
	if (data.type == PTHREAD_MUTEX_RECURSIVE)
	{
		ret = pthread_mutex_trylock(&(data.mtx));
		if (ret != 0)  {  FAILED("Unable to double-lock a recursive mutex in clean-up handler 1");  }
		ret = pthread_mutex_unlock(&(data.mtx));
		if (ret != 0)  {  UNRESOLVED(ret, "Unable to unlock double-locked recursive mutex in clean-up handler 1");  }
	}
	return;
}

/**** Second handler
 *  This one will trigger an action in main thread, while we are owning the mutex
 */
void pthread_cond_timedwait_2_6_clnp2 (void * arg)
{
	int ret;
	do {
		ret = sem_post(&(data.semA));
	} while ((ret != 0) && (errno == EINTR));
	if (ret != 0)  {  UNRESOLVED(errno, "Sem post failed in cleanup handler 2");  }

	do {
		ret = sem_wait(&(data.semB));
	} while ((ret != 0) && (errno == EINTR));
	if (ret != 0)  {  UNRESOLVED(errno, "Sem wait failed in cleanup handler 2");  }
	
	return;
}

/**** Third handler
 *  Will actually unlock the mutex, then try to unlock second time to check an error is returned
 */
void pthread_cond_timedwait_2_6_clnp3 (void * arg)
{
	int ret;

	ret = pthread_mutex_unlock(&(data.mtx));
	if (ret != 0)  {  UNRESOLVED(ret, "Unable to unlock mutex in clean-up handler 3");  }
	
	if ((data.type == PTHREAD_MUTEX_ERRORCHECK) || (data.type == PTHREAD_MUTEX_RECURSIVE))
	{
		ret = pthread_mutex_unlock(&(data.mtx));
		if (ret == 0)  {  UNRESOLVED(ret, "Was able to unlock unlocked mutex in clean-up handler 3");  }
	}
	
	return;
}
	

/**** Thread function
 * This function will lock the mutex, then install the cleanup handlers 
 * and wait for the cond. At this point it will be canceled.
 */
void * pthread_cond_timedwait_2_6_threaded (void * arg)
{
	int ret;
	
	struct timespec ts;
	
	ret = clock_gettime(data.cid, &ts);
	if (ret != 0)  {  UNRESOLVED(ret, "Unable to get time from clock");  }
	
	ts.tv_sec += 30;
	
	ret= pthread_mutex_lock(&(data.mtx));
	if (ret != 0)  {  UNRESOLVED(ret, "Failed to lock the mutex in thread");  }
	
        do {
                ret = sem_post(&(data.semA));
        } while ((ret != 0) && (errno == EINTR));
        if (ret != 0)  {  UNRESOLVED(errno, "Sem post failed in thread");  }

	pthread_cleanup_push ( pthread_cond_timedwait_2_6_clnp3, NULL);
	pthread_cleanup_push ( pthread_cond_timedwait_2_6_clnp2, NULL);
	pthread_cleanup_push ( pthread_cond_timedwait_2_6_clnp1, NULL);
	
	do {
		ret = pthread_cond_timedwait(&(data.cnd), &(data.mtx), &ts);
	} while ((ret == 0) && (data.bool == 0));
	
	if (ret != 0)  {  UNRESOLVED(ret , "Timedwait failed");  }  /* We will exit even if the error is timedwait */
	
	/* If we are here, the thread was not canceled */
	FAILED("The thread has not been canceled");
	
	pthread_cleanup_pop(0);
	pthread_cleanup_pop(0);
	pthread_cleanup_pop(1);
	
	return NULL;
}

int pthread_cond_timedwait_2_6(int argc, char * argv[])
{
	int ret, i;
	void * rc;

	pthread_mutexattr_t ma;
	pthread_condattr_t ca;
	pthread_t th;

	long altclk_ok, pshared_ok;
	
	struct 
	{
		char altclk;  /* Want to use alternative clock */
		char pshared; /* Want to use process-shared primitives */
		int type;     /* mutex type */
		char * descr; /* Description of the case */
		
	} scenar[] = 
	{ {0, 0, PTHREAD_MUTEX_NORMAL,     "Normal mutex" }
#ifdef USE_ALTCLK
	 ,{1, 0, PTHREAD_MUTEX_NORMAL,     "Normal mutex + altclock cond" }
	 ,{1, 1, PTHREAD_MUTEX_NORMAL,     "PShared mutex + altclock cond" }
#endif
	 ,{0, 1, PTHREAD_MUTEX_NORMAL,     "Pshared mutex" }
#ifndef WITHOUT_XOPEN
	 ,{0, 0, PTHREAD_MUTEX_ERRORCHECK, "Errorcheck mutex" }
	 ,{0, 0, PTHREAD_MUTEX_RECURSIVE , "Recursive mutex"  }
#ifdef USE_ALTCLK
	 ,{1, 0, PTHREAD_MUTEX_RECURSIVE , "Recursive mutex + altclock cond" }
	 ,{1, 0, PTHREAD_MUTEX_ERRORCHECK, "Errorcheck mutex + altclock cond" }
	 ,{1, 1, PTHREAD_MUTEX_RECURSIVE , "Recursive pshared mutex + altclock cond" }
	 ,{1, 1, PTHREAD_MUTEX_ERRORCHECK, "Errorcheck pshared mutex + altclock cond" }
#endif
	 ,{0, 1, PTHREAD_MUTEX_RECURSIVE , "Recursive pshared mutex" }
	 ,{0, 1, PTHREAD_MUTEX_ERRORCHECK, "Errorcheck pshared mutex" }
#endif
	};
	
	output_init();
	
	/* Initialize the constants */
	altclk_ok = sysconf(_SC_CLOCK_SELECTION);
	if (altclk_ok > 0)
		altclk_ok = sysconf(_SC_MONOTONIC_CLOCK);
#ifndef USE_ALTCLK
	if (altclk_ok > 0)
		output("Implementation supports the MONOTONIC CLOCK but option is disabled in test.\n");
#endif
	
	pshared_ok = sysconf(_SC_THREAD_PROCESS_SHARED);
	
	#if VERBOSE > 0
	output("Test starting\n");
	output(" Process-shared primitive %s be tested\n", (pshared_ok>0)?"will":"won't");
	output(" Alternative clock for cond %s be tested\n", (altclk_ok>0)?"will":"won't");
	#endif
	
	ret = sem_init(&(data.semA), 0, 0);
	if (ret != 0)  {  UNRESOLVED(errno, "Unable to init sem A");  }
	
	ret = sem_init(&(data.semB), 0, 0);
	if (ret != 0)  {  UNRESOLVED(errno, "Unable to init sem B");  }
	
	for (i=0; i< (sizeof(scenar) / sizeof(scenar[0])); i++)
	{
		#if VERBOSE > 1
		output("Starting test for %s\n", scenar[i].descr);
		#endif
		
		/* Initialize the data structure */
		ret = pthread_mutexattr_init(&ma);
		if (ret != 0)  {  UNRESOLVED(ret, "Mutex attribute object init failed");  }
		
		ret = pthread_mutexattr_settype(&ma, scenar[i].type);
		if (ret != 0)  {  UNRESOLVED(ret, "Unable to set mutex type");  }
		
		if ((pshared_ok > 0) && (scenar[i].pshared != 0))
		{
			ret = pthread_mutexattr_setpshared(&ma, PTHREAD_PROCESS_SHARED);
			if (ret != 0)  {  UNRESOLVED(ret, "Unable to set mutex process-shared");  }
		}
		
		ret = pthread_condattr_init(&ca);
		if (ret != 0)  {  UNRESOLVED(ret, "Cond attribute object init failed");  }
		
		if ((pshared_ok > 0) && (scenar[i].pshared != 0))
		{
			ret = pthread_condattr_setpshared(&ca, PTHREAD_PROCESS_SHARED);
			if (ret != 0)  {  UNRESOLVED(ret, "Unable to set cond process-shared");  }
		}
		
		#ifdef USE_ALTCLK
		if ((altclk_ok > 0) && (scenar[i].altclk != 0))
		{
			ret = pthread_condattr_setclock(&ca, CLOCK_MONOTONIC);
			if (ret != 0)  {  UNRESOLVED(ret, "Unable to set alternative (monotonic) clock for cond");  }
		}
		#endif
		
		ret = pthread_mutex_init(&(data.mtx), &ma);
		if (ret != 0)  {  UNRESOLVED(ret, "Unable to init mutex");  }
		
		ret = pthread_cond_init(&(data.cnd), &ca);
		if (ret != 0)  {  UNRESOLVED(ret, "Unable to initialize condvar");  }
		
		ret = pthread_mutexattr_gettype(&ma, &(data.type));
		if (ret != 0)  {  UNRESOLVED(ret, "Unable to get type from mutex attr");  }

		#ifdef USE_ALTCLK
		ret = pthread_condattr_getclock(&ca, &(data.cid));
		if (ret != 0)  {  UNRESOLVED(ret, "Unable to get clock ID from cond attr");  }
		#else
		data.cid = CLOCK_REALTIME;
		#endif
		
		data.bool = 0;
		
		/** Data is ready, create the thread */
		#if VERBOSE > 1
		output("Initialization OK, starting thread\n");
		#endif
		
		ret = pthread_create(&th, NULL, pthread_cond_timedwait_2_6_threaded, NULL);
		if (ret != 0)  {  UNRESOLVED(ret, "Thread creation failed");  }
		
                /** Wait for the thread to be waiting */
                do {
                        ret = sem_wait(&(data.semA));
                } while ((ret != 0) && (errno == EINTR));
                if (ret != 0)  {  UNRESOLVED(errno, "Sem wait failed in main");  }
		
		ret = pthread_mutex_lock(&(data.mtx));
		if (ret != 0)  {  UNRESOLVED(ret, "Unable to lock mutex in main");  }
		
		data.bool = 1;
		
		/** Cancel the thread */
		ret = pthread_cancel(th);
		if (ret != 0)  {  UNRESOLVED(ret, "Thread cancelation failed");  }
		
		sched_yield();
		#ifndef WITHOUT_XOPEN
		sleep(1);
		#endif
		
		ret = pthread_mutex_unlock(&(data.mtx));
		if (ret != 0)  {  UNRESOLVED(ret, "Unable to unlock mutex in main");  }
		
		/** Wait for the thread to be executing second cleanup handler */
		do {
			ret = sem_wait(&(data.semA));
		} while ((ret != 0) && (errno == EINTR));
		if (ret != 0)  {  UNRESOLVED(errno, "Sem wait failed in main");  }
		
		/** Here the child should own the mutex, we check this */
		ret = pthread_mutex_trylock(&(data.mtx));
		if (ret == 0)  {  FAILED("The child did not own the mutex inside the cleanup handler");  }
		
		/** Let the cleanups go on */
		do {
			ret = sem_post(&(data.semB));
		} while ((ret != 0) && (errno == EINTR));
		if (ret != 0)  {  UNRESOLVED(errno, "Sem post failed in main");  }
		
		/** Join the thread */
		ret = pthread_join(th, &rc);
		if (ret != 0)  {  UNRESOLVED(ret, "Unable to join the thread");  }
		if (rc != PTHREAD_CANCELED)  {  FAILED("thread was not canceled");  }
		
		#if VERBOSE > 1
		output("Test passed for %s\n", scenar[i].descr);
		#endif
		
		/* Destroy datas */
		ret = pthread_cond_destroy(&(data.cnd));
		if (ret != 0)  {  UNRESOLVED(ret, "Cond destroy failed");  }
		
		ret = pthread_mutex_destroy(&(data.mtx));
		if (ret != 0)  {  UNRESOLVED(ret, "Mutex destroy failed");  }
		
		ret = pthread_condattr_destroy(&ca);
		if (ret != 0)  {  UNRESOLVED(ret, "Cond attribute destroy failed");  }
		
		ret = pthread_mutexattr_destroy(&ma);
		if (ret != 0)  {  UNRESOLVED(ret, "Mutex attr destroy failed");  }
	} /* Proceed to next case */
	
	ret = sem_destroy(&(data.semA));
	if (ret != 0)  {  UNRESOLVED(errno, "Sem destroy failed");  }
	
	ret = sem_destroy(&(data.semB));
	if (ret != 0)  {  UNRESOLVED(errno, "Sem destroy failed");  }
	
	printf("Test PASS\n");
	PASSED;
}

